Excess Volumes and Isentropic Compressibilities ... - ACS Publications

71

J. Chem. Eng. Data 1992, 37, 71-74

Excess Volumes and Isentropic Compressibilities of Mixtures of 1,2-Dichlorobenzene Isopropyl Alcohol, Isobutyl Alcohol, and Isopentyl Alcohol at 303.15 K

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Vadlamoodl C. Kumar, Bojja Sreenlvasulu, and Pullgundla R. Naldu' Department of Chemistfy, University College, Sri Venkateswara University, Tirupati 5 17502,India

Excess volume and devlatlon In lsentroplc compresslblllty were measured for mlxtures of 1,2dlchloroben~enewlth Isopropyl alcohol, Isobutyl alcohol, and Isopentyl alcohol at 303.15 K. Excess volume exhibits lnverslon In sign In the three mlxtures. Thls Is slmllar to the trend between excess volume and composltlon observed In the mixtures of 1,2dlchlorobenrene wlth I-propanol, 1-butanol, and I-pentanol. However, the negatlve excess volume becomes domlnanl In mixtures of 1,2dlchlorobenzene wlth Isopropyl alcohol and Isobutyl alcohol. Deviation In lsentroplc compresslblllty Is negatlve over the whole range of composltlon and Is slmllar to that observed for the mixtures of 1,2dlchlorobenzene wlth the corresponding I-alkanols. However, a large negatlve devlatlon Is observed In mixtures of 1,2dlchlorobenzene wlth the lsoalcohols.

Introductlon Excess volumes ( VE)and isentropic compressibiliies (K,)for binary mixtures of 1,2dichlorobenzene with I-butanol and 1pentanol are reported in the lieratwe ( I,,?). While VE exhibited inversion in sign, deviation in isentropic compressibility was negative throughout the whole range of composition. We report here new experimental excess volumes and deviations in isentropic compressibiliies for mixtures of 1,2dichlorobenzene with isopropyl alcohol, isobutyl alcohol, and isopentyl alcohol. The results have been compared with those of the three corresponding lalcohds. The comparison was made to study the effect of branching of an alcohol on the two properties. The experimental data for the mixture 1,2dichlorobenzene 1propanol needed for the comparison were also determined in the present investigation.

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Experimental Section

of Pure Components at 303.15 K D / (a.cm") component lit. present study 1,2-dichlorobenzene 1.29922 1.299 19 1-propanol 0.796 00 0.796 02 isopropyl alcohol 0.776 90 0.776 85 isobutyl alcohol 0.794 37 0.794 35 isopentyl alcohol 0.801 79 0.801 78

Table I. Densities

(p)

Table 11. Mole Fraction of If-Dichlorobenzene (xl), Excess Volumes ( VE)for the Binary Mixtures of l&Dichlorobenzene with 1-Propanol and Isoalcohols at 303.15 K x, Vel (cm3.mol-') x1 VE/(cm3.mol-*) 1,2-Dichlorobenzene+ 1-Propanol 0.0663 -0.084 0.4918 -0.048 0.2341 -0.146 0.5946 0.005 0.3334 -0.125 0.7062 0.047 0.4329 -0.080 0.8450 0.059 0.0824 0.2005 0.3142 0.4650

1,2-Dichlorobenzene+ Isopropyl Alcohol -0.173 0.5066 -0.120 -0.264 0.6126 -0.038 -0.253 0.7219 0.028 -0.159 0.8312 0.064

0.1074 0.1791 0.2950 0.3887 0.4829

1,2-Dichlorobenzene+ Isobutyl Alcohol -0.155 0.6322 -0.207 0.7419 -0.215 0.7857 -0.177 0.8547 -0.132

0.1164 0.1975 0.2923 0.3896 0.5037

1,2-Dichlorobenzene+ Isopentyl Alcohol -0.135 0.5741 -0.064 -0.168 0.6878 -0.007 -0.174 0.7695 0.020 -0.147 0.8791 0.041 -0.094

-0.043 0.008 0.028 0.035

maintained to fO.O1 K. The density was computed from the measured excess volume using the relation

Excess volumes were measured directly by using the dialatometer described by Rao and Naidu (3). The mixing cell contained two bulbs of different capacities which were connected through a U tube with mercury to separate the two components. One end of the bulb was fiied with a capillary (l-mm i.d.), and the other end of the second bulb was fitted with a ground-glass stopper. The excess volumes were accurate to f0.003 cm3-mol-'. Isentropic compressibiliiies were computed from measured sound speed data and densities evaluated from excess volumes. The ultrasonic sound speed was measured with a single-crystal interferometer at 4-MHz frequency, and the data were accurate to f0.15 % All the measurements were made at constant temperature, employing a thermostat that could be

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To whom correspondence should be addressed.

0021-9568/92/ 1737-007 1$03.00/0

where M, p1,2, V o , and x represent the molecular weight, density, molar volume of the ideal mixture, and mole fraction of the mixture, respectively.

Purlflcatlon of Materlals All the materials were purified by the methods described by Riddick and Bunger (4). 1,2-Dichlorobenzene (S. D. Fine Chemicals) was passed through alumina in a 30 X 2 cm column and fractionally distilled. All alcohols were dried by re0 1992 American Chemical Society

72 Journal of Chemical and Engineering Data, Vol. 37, No. 1, 1992

Table 111. Standard Deviation u( VE)and Values of Constants in Equation 1 system ao/ (cm3.mol-*) a1/(cm3.mol-') 1,2-dichlorobenzene + 1-propanol -0.1687 1.0945 1.2-dichlorobenzene + isopropyl alcohol -0.5015 1.7079

1;2-dichlorobenzene + isobutyi alcohol 1,2-dichlorobenzene+ isopentyl alcohol

-0.4816 -0.3969

a,/(cm3.mol-') -0.3017 -0.4634 -0.2567 -0.1083

1.2500 1.0659

u( P)/(cm3.mol-')

0.002 0.006 0.004 0.005

Table IV. Volume Fractions (&), Densities (p), Sound Velocities ( u ), Isentropic Compressibilities ( K s ) and , the Deviations in Isentropic Compressibilities ( A R B )of 1,2-Dichlorobenzenewith 1-Propanol and Isoalcohols at 303.15 K 4' p/(g-~m-~) u/(ms-l) Ks/TPa-' AKs/TPa-'

-' -

0

E

m

E

0

O.oo00 0.0962 0.3142 0.4284 0.5336 0.5919 0.6873 0.7827 0.8909 1.oo00

1,2-Dichlorobenzene + 1-Propanol 0.79602 1219 845 793 0.84533 1221 0.95575 1228 694 1.01303 1229 654 619 1.06543 1231 1.09440 1232 602 574 1.14179 1235 546 1.18931 1241 1.24363 1249 515 480 1.29919 1266

O.oo00 0.1161 0.2684 0.4012 0.5597 0.6003 0.6981 0.7915 0.8781 1.0000

1,2-Dichlorobenzene + Isopropyl Alcohol 0.77685 1138 994 0.83930 1156 892 0.91989 1174 789 0.98925 1185 720 1.07102 1200 648 1.09177 1203 633 1.14195 1215 593 558 1.18997 1227 1.23477 1244 523 1.29919 1266 480

1 w

>

-0.28L 0.0

0.2

0.6

0.4

0.8

1

X1

Figure 1. Mole fraction of 1,2dichlorobenzene with isoalcohols or l-alcohols. VE plotted against the mole fraction ( x , ) of 1,2dichlorobenzene with isopropyl alcohol and 1-propanol at 303.15 K.

fluxing with fused calcium oxide and finally distilled using a fractionating column. The purity of the sample was checked by comparing the measured density of the compounds with those reported in the literature (4, 5). Densities were determined wlth a bicapillary type pycnometer, which offered an accuracy of 2 parts in lo5. The measured densities and those reported in the lierature are given in Table I.

Results and Dlscusslon Experimental results for excess volumes of mixtures of 1,2dichlorobenzene with 1-propanol, isopropyl alcohol, isobutyl alcohol, and isopentyl alcohol are included in Table 11. The results are also graphically presented along with those for the mixture of the common component with the corresponding 1-alkanols in Figures 1-3. Experimental VE data have been reduced using the polynomial

where xl, x 2 denote mole fractions of components 1 and 2 and a, a 1, a are constants. The values of the constants obtained by the least-squares method are given in Table 111, along with the standard deviation a( VE). Experimental sound speed ( u ) data and density (p) computed from measured excess volume data are presented in columns

1.Oooo

1,2-Dichlorobenzene+ --obutylAlcohc 0.79435 1173 915 0.86003 1194 816 0.90190 1201 769 0.96638 1201 717 1.01592 1200 684 1.06381 1204 648 1.13597 1214 597 1.18656 1228 559 1.20618 1232 546 1.23672 1242 524 1.29919 1266 480

O.oo00 0.1194 0.2021 0.2983 0.3965 0.5109 0.5811 0.6939 0.7746 0.8821 1.0000

1,2-Dichlorobenzene + Isopentyl Alcohol 0.80178 1214 846 0.86222 1220 779 0.90368 1225 737 0.95164 1227 698 1.00030 1226 665 1.05679 1229 626 1.09145 1233 603 1.14702 1239 568 1.18684 1243 545 1.24010 1251 515 1.29919 1266 480

O.oo00 0.1273 0.2092 0.3366 0.4354 0.5310 0.6758 0.7771 0.8164 0.8770

-17 -36 -35 -31 -27 -20 -13 -5

-42 -67 -68 -58 -52 -42 -29 -20

-44 -55 -52 -42 -36 -24 -18 -14 -10

-23 -35 -39 -36 -33 -30 -24 -18 -8

3 and 2, respectively, of Table IV. Isentropic compressibility K , and deviation in isentropic compressibility AKs are calculated using the equations

X1Vl0 $1

= x1V1O 42

+ x,V,O

= 1 - 41

where K,, K,,, and K,, represent isentropic compressibiiitles

Journal of Chemical and Englneering Data, Vol. 37,

No. 1, 7992 73

t

-0,241 0.0

0.2

0.6

0.4

0.8

1

k-4 &--A X--*

1,2 DCB. 1,20CB. 1.2 D C B . " 4 1.2 DCB

X i

Flgure 2. Mole fraction of 1,2dlchlorobenzene with isoalcohois or lalcohols. V Eplotted against the mole fraction ( x , ) of 1,2dichlorobenzene with isobutyl alcohol and 1-butanol at 303.15 K.

lsObutonOl

I-butanol Isopmtonol 1-pmtonot

-80-

Table V. Standard Deviation a ( A K s ) and Values of Constants in Equation 6

system bo/TPa-' bl/TPa-' b2/TPa-' 1,2-dichlorobenzene+ -131.0 92.0 12.6 1-propanol 1,2-dichlorobenzene+ -248.0 153.0 -80.2 isopropyl alcohol 1,2-dichlorobenzene+ -153.0 199.0 -170.0 isobutyl alcohol 1,2-dichlorobenzene+ -140.0 94.1 -26.0 isopentyl alcohol

\

' -4,'

2

/

+.G

1,2 OCB+Isopentonol

L--4 1,2 OCE+l-pentonol 0 2

0 6

0 4

08

1.0

*1

Flgure 3. Mole fraction of 1,2dichlorobenzene with isoalcohols or lalcohols. V E plotted against the mole fraction ( x , ) of 1,2dichlorobenzene with isopentyl alcohol and I-pentanoi at 303.15 K.

of a mixture and the pure components 1 and 2, respectively. 4 and 4 denote volume fractions of the components. The values of K, and AKs are included in columns 4 and 5 of Table IV. The results are graphically represented along with those for mixtures of 1,2dichiorobenzene with 1-propanol, 1-butanol, and 1-pentanol in Figure 4.

,

2

\ \

-0'16-

00

1

These resutts also have been fitted into an empirical equation of the form

-0.12-

-020

u(AKs)/ TPa-' 0

The numerical values of the constants b o , b ,, and b are included in Table V, along with the standard deviation a(AK,). The results in Table I 1 show that VE exhibits inversion in sign in the three binary mixtures. However it remains negative over a large range of composition. The curves in Figures 1-3 show that replacement of 1-propanol and 1-butanol by the corresponding isoalcohols leads to a more negative value of VE. However the replacement of 1-pentanol by lsopentyl alcohol does not change the value of VE to a significant extent. The deviation in the isentropic compressibility AK, is negative over the whole range of composition. The curves in Figure 4 indicate that deviation becomes more negative in mixtures of 1,2dichlorobenzene with the three isoalcohols. Registry No. 1.2 DCB, 95-50-1; isopropyl alcohol, 67-63-0; isobutyl alcohol, 78-83-1; isopentyl alcohol, 123-51-3.

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J. Chem. Eng. Data 1992, 3 7 , 74-76

Llterature Clted (1) Vijayalakshmi, T. S.; N a b , P. R. J. Chem. Eng. Data 1080, 3 4 , 413. (2) Vijayalakshmi, T. S.; Naidu, P. R. Indisn J. Pure Appl. Phys. 1000, 28, 215. (3) Rao, M. V. P.; Naidu, P. R. Can. J. Chem. 1974, 52, 788-90.

(4) Riddick,, J. A.; Bunger, W. B. Techniques of Chemistry,3rd ed.; WiieyInterscience: New York, 1970. ( 5 ) Timmermans, J. Physico-chemical consfanfs of pure organic compounds; Eisevier: New York, 1950. Received for review April 30, 1991. Revised September 17, 1991. Accepted September 26, 1991.

Vapor-Liquid Coexistence Curve and the Critical Parameters of 1-Chloro-I ,I-difluoroethane (HCFC-142b) Selsho Tanikawa, Jun Tatoh, Yukishige Maezawa, Harukl Sato, and Koichi Watanabe Deparfment of Mechanical Engineering, Faculty of Science and Technology, Keio University, 3- 14- 1, Hiyoshi, Kohoku-ku, Yokohama 223, Japan

Vapor-liquid coexlstence curve near the crltlcal polnt of 1-chioro-1,l-difluoroethane (HCFC-142b) was measured by a visual observation of the menlscus In an optlcal cell. Saturation densities lncludlng 13 saturated-vapor and 18 saturated-llquld densities were obtained In the range of temperature from 354 K to the critical temperature, correspondlng to the density range from 181 to 947 kg/m3. The experlmentai errors In temperature and density were estimated to be within f l O mK and between fO.09 and f0.53%, respectively. Not only the level where the menlscus disappeared but also the Intensity of the critical opalescence were consldered for the determination of the critical temperature and density as 410.29 f 0.02 K and 446 f 3 kg/m3, respectlvely. The critical exponent, 8, was also determined to be 0.339 f 0.002. A saturated-vapor/saturated-iiquld denslty correlatlon was developed on the basis of the present measurements. Introduction HCFC-142b (1-chloro-1,ldifluoroethane) is one of the environmentally acceptable refrigerants. A binary mixture of HCFC-22 (chlorodifluoromethane) HCFG142b has the possibility of becoming a promising substitute for CFC-12 (dichlorodifluoromethane). We have already reported the critical parameters of several CFC-alternative refrigerants, Le., HFC152a ( 1 ) , HFC134a (2), and WFC-123 (3). This paper reports the measured vapor-liquid coexistence curve in the critical region, the experimentally determined critical temperature, density, and exponent, and a saturation density correlation for HCFC-142b.

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Experlmentai Section A visual observation apparatus, originally built by Okazaki et al. ( 4 ) and redesigned by Tanikawa et al. (3), was used for all measurements. The apparatus and procedure have been reported in detail in our previous publications (3-6). Temperature measurements were performed by using a standard platinum resistance thermometer, and measured temperatures were converted into two different temperature scales of IPTS68 and ITS-90. All the descriptions given in figures and correlations in the present paper are exclusively dependent on the temperature scale of IPTS-68. The thermometer was put * To whom correspondence should be addressed.

0021-9568/92/1737-0074$03.00/0

Table I. Saturated-Vapor Densities p" of HCFC-142bO

T68/K (Tw/K) 395.833 (395.802) 399.071 (399.039) 402.747 (402.714) 404.660 (404.627) 405.739 (405.706) 408.218 (408.185) 408.693 (408.660)

d'/(kg/m3) 181.3 f 1.0' 202.8 f 0.8' 232.8 f 0.9' 252.4 f 0.4' 266.9 f 0.5' 308.5 f 0.3' 318.3 f 0.5'

T68/K (Tw/K) 408.991 (408.958) 409.956 (409.922) 410.232 (410.198) 410.295 (410.261) 410.292 (410.258) 410.293 (410.259)

d'/(kg/m3) 326.3 f 0.3' 365.5 f 0.6** 389.1 f 0.4*' 412.8 f 0.8** 438.0 f 0.4*c 442.0 f 0.7*'

Values marked with asterisks are from points at which critical opalescence was observed. 'Sample with 99.8 mass % purity was used. 'Sample with 99.9 mass % purity was used. Table 11. Saturated-Liauid Densities D' of HCFC-142b4rd ..

410.282 (410.249) 410.283 (410.250) 410.290 (410.255) 410.281 (410.248) 410.222 (410.188) 409.645 (409.612) 408.450 (408.417) 407.686 (407.652) 406.465 (406.432)

446.0 f 0.4*' 446.8 f 0.4*' 453.6 f 0.5*c 473.3 f 0.5*' 493.5 f l.l*' 546.0 f: 0.5' 584.9 f 1.5' 603.4 f 1.0' 626.4 f 1.3'

403.306 (403.274) 398.562 i398.53oj 396.188 (396.157) 391.694 (391.664) 387.434 (387.405) 382.291 (382.263) 376.617 (376.590) 369.842 (369.813) 353.548 (353.527)

. -. 670.8 f 0.9' 718.5 i 0.66 738.2 f 0.7' 770.2 f 1.9' 796.9 f 1.1' 825.1 f 1.7' 853.8 f 0.8' 884.1 f 1.2' 947.4 f 0.9'

See Table Ifor footnotes a-c.

in the vicinity of optical cell at the same level in the bath. The experimental uncertainty in temperature was estimated to be within f10 mK as the sum of 2 mK, the precision of the thermometer; 1 mK, the precision of the bridge: and 7 mK, the possible temperature fluctuation of the silicone oil in the bath. The value of the resistance measured with our thermometer at the triple point of water altered by 0.000 03 Q. The uncertainty in density was estimated to be between f0.09%, which is considered to be due to the uncertainties of the cell volumes and the sample mass, and f0.53 % , which includes the uncertainty of the expansion factor. The purlties of the two samples furnished by manufacturers were 99.8 and 99.9 mass %.

Results The saturated-vapor densities were measured at temperatures above 396 K (0.965 in reduced temperature) and at densities between 181 kg/m3 (0.407 in reduced denslty) and 442 kg/m3, whereas the saturatedliquid densities were measured above 354 K (0.862) and between 446 and 947 kg/m3 (2.124). The experimental results including 13 saturated-vapor and 18 saturated-liquid densities are listed in Tables I and 11. 0 1992 American Chemical Society